LED package and the process making the same

ABSTRACT

Light emitting diode (LED) packages are made by first providing a platelike frame having a plurality of cells, each of which is composed of a main plate and a separate arm. Secondly, an LED die and a reflecting ring are respectively mounted on top of each main plate such that the die is located at a center of the reflecting ring. Then a conductive wire is connected between the top surface of the die and a top surface of the separate arm by wire bonding. A domed transparent encapsulant is then molded on each of the cells. The encapsulant encapsulates the die, the reflecting ring and the conductive wire and covers the main plate and the separate arm, and fills a space between the main plate and the separate arm to remain their spaced apart. Finally, the frame is cut according to the size of each cell to obtain the LED packages.

This is a division of parent application Ser. No. 10/263,805, filed Oct. 4, 2002, now U.S. Pat. No. 6,770,498.

FIELD OF THE INVENTION

The present invention relates generally to photoelectric semiconductor, and more particularly to a process for fabricating a light emitting diode (LED) package and the structure of the LED package.

BACKGROUND OF THE INVENTION

A conventional lamp-typed LED package is made by the following process. Firstly, provide a frame made of an electrically conductive metal. The frame has a numbers of pairs of leads arranged parallel and interconnected with each others through a cross bar. Each pair of leads is served as a positive pole and a negative pole of one LED package. On one of the poles, generally the negative pole, a bowl-shaped recess defining a reflecting surface for reflecting light is formed. Next, an LED die is attached on a bottom of the bowl-shaped recess of each negative pole by an electrically conductive adhesive, e.g. silver adhesive, such that an N-electrode of the LED die is electrically connected to the negative pole. Then, a P-electrode of each LED die is electrically connected to the other lead, i.e. the positive pole, through a gold wire by wire-bonding technique. By means of a molding technique, the LED dies are then respectively encased by a dome-shaped epoxy resin encapsulant with the metallic leads partially projecting out of the respective encapsulant and the cross bar is exposed outside the encapsulants. Finally, the cross bar is cut to obtain a. numbers of LED packages.

Compared with other lighting devices, such as fluorescent lamps and incandescent lamps, the heat emitted by the LED package is low, but a certain amount of the heat, which is generated while the LED die glows by the electricity of from tens to hundreds of milliamperes, is a major factor resulted in the damage of the LED package. Accordingly, the present research and improvement is also focused on reducing the heat generated by the LED die. As far as the foregoing prior art LED package is concerned, the die is encapsulated in the epoxy encapsulant, which thermal conductivity is poor, and the contact area between the die and one of the leads is small. Besides, a protrudent portion of the leads out of the encapsulant is in the shape of a thin bar, so that the thermal conductivity of the above-mentioned conventional LED package is very poor and further improvement is required.

SUMMARY OF THE INVENTION

The primary objective of the present invention is to provide a process for fabricating LED packages, whereby a better thermally conductive and durable LED packages are made.

To achieve the foregoing objective of the present invention, the process for fabricating LED packages involves the following steps. Step A: Provide a platelike frame made of an electrically conductive metal. The frame has a plurality of cells, each of which includes a main plate and a separate arm, and no connection but a space between the main plate and the separate arm. Step B: Attach an LED die on a top surface of each main plate of the frame so as to electrically connect an electrode on a bottom side of the die to the main plate. Moreover, form a reflecting ring on each main plate with a molding technique, wherein the reflecting ring is made of opaque white plastic and has an upward sloping inner surface, and the die is positioned in the center of the reflecting ring. Step C: Connect the other electrode on a top surface of the die to a top surface of the separate arm with a conductive wire by means of wire bonding technique. Step D: Form an encapsulant on each cell of the frame with epoxy resin by means of the molding technique, wherein the encapsulant encapsulates the die, the reflecting ring and the conductive wire, and covers the main plate and the separate arm and also fills the space between the main plate and the separate arm to remain their spaced apart in opposite relationship. Additionally, the encapsulant has a top domelike protrusion. Step E: Cut the platelike frame substantially according to the size of each of the cells such that a plurality of LED packages are made.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flow chart showing a process for fabricating LED packages of a preferred embodiment in accordance with the present invention;

FIG. 2 shows semi-finished LED packages of the first step according to FIG. 1;

FIG. 3 is a cross-sectional view taken along the direction indicated by the line 3—3 as shown in FIG. 2;

FIG. 4 shows semi-finished LED packages of the second step according to FIG. 1;

FIG. 5 is a cross-sectional view taken along the direction indicated by the line 5—5 as shown in FIG. 4;

FIG. 6 shows semi-finished LED packages of the third step according to FIG. 1;

FIG. 7 is a cross-sectional view taken along the direction indicated by the line 7—7 as shown in FIG. 6;

FIG. 8 shows semi-finished LED packages of the fourth step according to FIG. 1;

FIG. 9 is a cross-sectional view taken along the direction indicated by the line 9—9 as shown in FIG. 8;

FIG. 10 shows semi-finished LED packages of the fifth step according to FIG. 1;

FIG. 11 is a cross-sectional view taken along the direction indicated by the line 11—11 as shown in FIG. 10; and

FIG. 12 shows a finished LED package of the preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The preferred embodiment of the present invention is to provide a process for fabricating white LED packages. However, it is to be understood that this process can be applied to make any kind of the LED lamp packages. Referring to FIG. 1, a flow chart of a fabricative process of the present invention includes six steps of plate-like frame providing, die bonding, reflecting ring molding, wire bonding, encapsulant molding, and cutting. The details of the steps will be illustrated hereunder with the accompanying drawings.

Referring to FIGS. 2-3, firstly, provide a plate-like frame 10, which is substantially rectangle and has a plurality of cells 11. The cells 11, each of which has a plurality of openings, are well positioned in an arrangement of matrix. Namely, the cells 11 are surrounded by left and right lateral sides, which are defined as two longitudinal lateral bars 12, and upper and lower sides, which are defined as two transversal lateral bars 13, wherein each of the cells 11 is comparted by a plurality of longitudinal dividing bars 14 and transversal dividing bars 15. The openings of the cell 11 are alike in shape, that is, the cell 11 has a rectangle main plate 16 at a center thereof, and two bridges 17 respectively at two centers of the upper and the lower lateral sides to connect the main plate 16 and the transversal dividing bar 15 or the transversal lateral bars 13, and an extending arm 18 at the middle of right lateral side of the cell 11 to connect the main plate 16 and the longitudinal dividing bars 14 or the longitudinal lateral bars 12, and a separate arm 19 at the middle of left lateral side of the cell 11 to connect only the longitudinal dividing bar 14 or the longitudinal lateral bar 12 but to be spaced apart from the main plate 16.

Step 2: Referring to FIGS. 4-5, a white LED die 20 is bonded on a top surface of each of the main plates 16 of the frame 10 by means of silver adhesives (not shown). The die 20 has a bottom to be smoothly bonded on the top surface of the main plate 16 such that an electrode positioned on the bottom of the die 20 directly electrically contacts the main plate 16 by means of the silver adhesive. Please note that the LED die 20 is a prior art, which epitaxy structure and how to glow are irrelevant to the present invention, will not recited thereafter. In addition, the technique of die bonding is also a prior art.

Step 3: Referring to FIGS. 6-7, form a reflecting ring 30, which is bonded on each of the main plates 16 of the frame 10, with plastic materials by means of injection molding technique. The reflecting ring 30, which axial height is almost the same with the die's 20 and which is made of opaque white material, surrounds the die 20 and has an inner surface 31, which is a slope facing upward with an angle of 45° to reflect the light emitted by the die 20. Further, to facilitate the molding operation, the neighboring reflecting rings 30 in the same row are connected with a connecting bar 32, which is mounted on the bridges 17 of the frame 10. The applicant would like to clarify that the step 3 can be prior to step 2, i.e., form the reflecting ring 30 on the frame 10 first, and then bond the die 20 on the main plate.

Step 4: Referring to FIGS. 8-9, connect a top surface of the die 20 to a top surface of the separate arm 19 of the cell 11 with a gold conductive wire 40 of 99% Au by wire bonding technique such that the other electrode positioned on the top surface of the die 20 can be electrically connected with the separate arm 19.

Step 5: Referring to FIGS. 10-11, form an encapsulant 50 on each of the cells 11 of the frame 10 with epoxy resin by means of the injection molding technique. The encapsulant 50 has a rectangle base 51, which corresponds to the cell 11 in size and fills the openings of the cell 11 and covers the surface of the frame 10 with a predetermined thickness. All the bases 51 of the encapsulants 50 are integrated together initially, so that the encapsulants 50 not only cover the main plates 16, the bridges 17, the extending arms 18 and the separate arms 19 of the cells 11 but also the dividing bars 14 and 15 of the frame 10. In this embodiment of the present invention, the base 51 is higher than the frame 10 and substantially as high as the reflecting ring 30. The encapsulant 50 has a top domelike protrusion 52, which is located on the top of the base 51 and integrated with the base 51, and not only encapsulates the die 20, the reflecting ring 30, and the conductive wire 40 on the cell 11 to maintain the mechanism of the die 20 and to prevent water from infiltration, but also reflects the light emitted by the die 20 through the inner surface 31 of the reflecting ring 30. In addition, the encapsulant 50 is an insulator.

Step 6: Cut the frame 10 according to the size of each of the cell 11, or smaller, by cutting out the lateral bars 12 and 13 and the dividing bars 14 and 15 of the frame 10 such that LED packages 60 are made.

Referring to FIGS. 11-12, the LED 60 package made by the foregoing fabricative process structurally includes a first terminal 70, a second terminal 80, the LED die 20, the reflecting ring 30, the conductive wire 40, and the encapsulant 50. The first terminal 70 is formed by the main plate 16, the extending arm 18 located at a right side of the main plate 16, and the bridges 17 respectively located at upper and lower sides of the main plates 16. Additionally, the first terminal 70 is made of an electrically conductive metal. The second terminal 80, which is the separate arm 19, is located at a left side of the first terminal 70 and spaced an appropriate distance apart from the first terminal 70 and made of the same electrically conductive metal. The LED die 20 has a bottom, which is smoothly bonded to a top surface of the main plate 16 of the first terminal 70 such that an electrode at the bottom of the LED die 20 is electrically connected to the first terminal 70. The reflecting ring 30, which is made of an opaque white plastic material, is molded on the top surface of the main plate 16 of the first terminal 70 by means of the injection molding technique and surrounds the die 20 and has the inner surface 31 facing upward as a slope. The conductive wire 40 is connected between the other electrode of the top surface of the die 20 and the top surface of the second terminal 80. The encapsulant 50, which material is the insulated epoxy resin with high transparency, encapsulates the die 20, the reflecting ring 30, and the conductive wire 40. Additionally, the base 51 of the encapsulant 50 covers the top surface of the first terminal 70 and the second terminal 80 and fills the space therebetween to remain two terminals 70 and 80 spaced apart in opposite relationship. The top of the encapsulant 50 is formed as the domed protrusion 52. When the LED package 60 is in use, generally take the first terminal 70 as positive electrode and the second terminal 80 as negative electrode such that the LED die 20 is charged by the electricity to emit white light. The emitted white light is then reflected from the inner surface 31 of the reflecting ring 30 to the dome-shaped protrusion of the encapsulant 50.

As a conclusion, the LED die 20 has a bottom being smoothly bonded on the top surface of the metallic main plate 16, so that the contact area between the die 20 and the main plate 16 is preferably large. Moreover, the main plate 16, more precisely, the first terminal 70 has a large bottom surface to be totally exposed outside, so that the heat generated by the die 20 can be conducted to the first terminal 70 and further conducted outside from the bottom surface of the first terminal 70 while the LED package 60 is charged. Therefore, the LED package 60 of the present invention is provided with excellent efficiency of thermal dissipation so as to be durable for a long time. 

1. An LED package comprising: a platelike first terminal made of an electrically conductive metal; a second terminal made of the electrically conductive metal and located at a side of said first terminal and spaced apart from said first terminal with a predetermined space; an LED die having a bottom bonded on a top surface of said first terminal such that an electrode located on the bottom of said die is electrically connected to said first terminal; a reflecting ring made of opaque white plastic and formed on the top surface of said first terminal by means of the molding technique to surround said die, said reflecting ring being provided with an upward sloping inner surface; a conductive wire connected the other electrode on a top surface of said die to a top surface of said second terminal, and an encapsulant made of insulated transparent epoxy resin encapsulating all the exposed surfaces of said die, said reflecting ring and said conductive wire and covering top surfaces of said first terminal and said second terminal, extending down from said top surfaces to cover exposed sides of said first terminal and said second terminal down to bottom surfaces thereof while filling the space between the first and second terminals down to said bottom surfaces to maintain said first terminal and said second terminal spaced apart.
 2. The LED package as defined in claim 1, wherein said first terminal has a main plate, on which top surface said die and said reflecting ring are mounted, connecting an extending arm at another side of said first terminal.
 3. The LED package as defined in claim 1, wherein said die is a white LED die.
 4. The LED package as defined in claim 1, wherein said sloping inner surface of said reflecting ring has a sloping angle of 45°.
 5. The LED package as defined in claim 1, wherein an exposed end of each of said first terminal and said second terminal is flush with a Bide of said encapsulant.
 6. The LED package as defined in claim 1, wherein the encapsulant has a rectangular base.
 7. The LED package as defined in claim 6, wherein said encapsulant has a top dome protrusion having apex extending up from said rectangular base.
 8. The LED package as defined in claim 1, wherein the encapsulant entirely covers the top surfaces of said first terminal and said second terminal. 